/*
 * Copyright 2009 Nicolai Hähnle <nhaehnle@gmail.com>
 * SPDX-License-Identifier: MIT
 */

#include "r300_reg.h"
#include "radeon_code.h"
#include "radeon_compiler.h"

#include <stdio.h>

static const char *r300_vs_ve_ops[] = {
   /* R300 vector ops */
   "                 VE_NO_OP",
   "           VE_DOT_PRODUCT",
   "              VE_MULTIPLY",
   "                   VE_ADD",
   "          VE_MULTIPLY_ADD",
   "       VE_DISTANCE_FACTOR",
   "              VE_FRACTION",
   "               VE_MAXIMUM",
   "               VE_MINIMUM",
   "VE_SET_GREATER_THAN_EQUAL",
   "         VE_SET_LESS_THAN",
   "        VE_MULTIPLYX2_ADD",
   "        VE_MULTIPLY_CLAMP",
   "            VE_FLT2FIX_DX",
   "        VE_FLT2FIX_DX_RND",
   /* R500 vector ops */
   "      VE_PRED_SET_EQ_PUSH",
   "      VE_PRED_SET_GT_PUSH",
   "     VE_PRED_SET_GTE_PUSH",
   "     VE_PRED_SET_NEQ_PUSH",
   "         VE_COND_WRITE_EQ",
   "         VE_COND_WRITE_GT",
   "        VE_COND_WRITE_GTE",
   "        VE_COND_WRITE_NEQ",
   "           VE_COND_MUX_EQ",
   "           VE_COND_MUX_GT",
   "          VE_COND_MUX_GTE",
   "      VE_SET_GREATER_THAN",
   "             VE_SET_EQUAL",
   "         VE_SET_NOT_EQUAL",
   "               (reserved)",
   "               (reserved)",
   "               (reserved)",
};

static const char *r300_vs_me_ops[] = {
   /* R300 math ops */
   "                 ME_NO_OP",
   "          ME_EXP_BASE2_DX",
   "          ME_LOG_BASE2_DX",
   "          ME_EXP_BASEE_FF",
   "        ME_LIGHT_COEFF_DX",
   "         ME_POWER_FUNC_FF",
   "              ME_RECIP_DX",
   "              ME_RECIP_FF",
   "         ME_RECIP_SQRT_DX",
   "         ME_RECIP_SQRT_FF",
   "              ME_MULTIPLY",
   "     ME_EXP_BASE2_FULL_DX",
   "     ME_LOG_BASE2_FULL_DX",
   " ME_POWER_FUNC_FF_CLAMP_B",
   "ME_POWER_FUNC_FF_CLAMP_B1",
   "ME_POWER_FUNC_FF_CLAMP_01",
   "                   ME_SIN",
   "                   ME_COS",
   /* R500 math ops */
   "        ME_LOG_BASE2_IEEE",
   "            ME_RECIP_IEEE",
   "       ME_RECIP_SQRT_IEEE",
   "           ME_PRED_SET_EQ",
   "           ME_PRED_SET_GT",
   "          ME_PRED_SET_GTE",
   "          ME_PRED_SET_NEQ",
   "          ME_PRED_SET_CLR",
   "          ME_PRED_SET_INV",
   "          ME_PRED_SET_POP",
   "      ME_PRED_SET_RESTORE",
   "               (reserved)",
   "               (reserved)",
   "               (reserved)",
};

/* XXX refactor to avoid clashing symbols */
static const char *r300_vs_src_debug[] = {
   "t",
   "i",
   "c",
   "a",
};

static const char *r300_vs_dst_debug[] = {
   "t",
   "a0",
   "o",
   "ox",
   "a",
   "i",
   "u",
   "u",
};

static const char *r300_vs_swiz_debug[] = {
   "X",
   "Y",
   "Z",
   "W",
   "0",
   "1",
   "U",
   "U",
};

static void
r300_vs_op_dump(uint32_t op)
{
   fprintf(stderr, " dst: %d%s op: ", (op >> 13) & 0x7f, r300_vs_dst_debug[(op >> 8) & 0x7]);
   if ((op >> PVS_DST_PRED_ENABLE_SHIFT) & 0x1) {
      fprintf(stderr, "PRED %u", (op >> PVS_DST_PRED_SENSE_SHIFT) & 0x1);
   }
   if (op & 0x80) {
      if (op & 0x1) {
         fprintf(stderr, "PVS_MACRO_OP_2CLK_M2X_ADD\n");
      } else {
         fprintf(stderr, "   PVS_MACRO_OP_2CLK_MADD\n");
      }
   } else if (op & 0x40) {
      fprintf(stderr, "%s\n", r300_vs_me_ops[op & 0x1f]);
   } else {
      fprintf(stderr, "%s\n", r300_vs_ve_ops[op & 0x1f]);
   }
}

static void
r300_vs_src_dump(uint32_t src)
{
   fprintf(stderr, " reg: %d%s swiz: %s%s/%s%s/%s%s/%s%s\n", (src >> 5) & 0xff,
           r300_vs_src_debug[src & 0x3], src & (1 << 25) ? "-" : " ",
           r300_vs_swiz_debug[(src >> 13) & 0x7], src & (1 << 26) ? "-" : " ",
           r300_vs_swiz_debug[(src >> 16) & 0x7], src & (1 << 27) ? "-" : " ",
           r300_vs_swiz_debug[(src >> 19) & 0x7], src & (1 << 28) ? "-" : " ",
           r300_vs_swiz_debug[(src >> 22) & 0x7]);
}

void
r300_vertex_program_dump(struct radeon_compiler *compiler, void *user)
{
   struct r300_vertex_program_compiler *c = (struct r300_vertex_program_compiler *)compiler;
   struct r300_vertex_program_code *vs = c->code;
   unsigned instrcount = vs->length / 4;
   unsigned i;

   fprintf(stderr, "Final vertex program code:\n");

   for (i = 0; i < instrcount; i++) {
      unsigned offset = i * 4;
      unsigned src;

      fprintf(stderr, "%d: op: 0x%08x", i, vs->body.d[offset]);
      r300_vs_op_dump(vs->body.d[offset]);

      for (src = 0; src < 3; ++src) {
         fprintf(stderr, " src%i: 0x%08x", src, vs->body.d[offset + 1 + src]);
         r300_vs_src_dump(vs->body.d[offset + 1 + src]);
      }
   }

   fprintf(stderr, "Flow Control Ops: 0x%08x\n", vs->fc_ops);
   for (i = 0; i < vs->num_fc_ops; i++) {
      unsigned is_loop = 0;
      switch ((vs->fc_ops >> (i * 2)) & 0x3) {
      case 0:
         fprintf(stderr, "NOP");
         break;
      case 1:
         fprintf(stderr, "JUMP");
         break;
      case 2:
         fprintf(stderr, "LOOP");
         is_loop = 1;
         break;
      case 3:
         fprintf(stderr, "JSR");
         break;
      }
      if (c->Base.is_r500) {
         fprintf(stderr,
                 ": uw-> 0x%08x lw-> 0x%08x "
                 "loop data->0x%08x\n",
                 vs->fc_op_addrs.r500[i].uw, vs->fc_op_addrs.r500[i].lw, vs->fc_loop_index[i]);
         if (is_loop) {
            fprintf(
               stderr, "Before = %u First = %u Last = %u\n", vs->fc_op_addrs.r500[i].lw & 0xffff,
               (vs->fc_op_addrs.r500[i].uw >> 16) & 0xffff, vs->fc_op_addrs.r500[i].uw & 0xffff);
         }
      } else {
         fprintf(stderr, ": 0x%08x\n", vs->fc_op_addrs.r300[i]);
      }
   }
}
